Evidence for Bolgiano-Obukhov scaling in rotating stratified turbulence using high-resolution direct numerical simulations

Rosenberg, Duane; Pouquet, A.; Marino, Raffaele; Mininni, Pablo D.

doi:10.1063/1.4921076

Cited by 64 publications

(81 citation statements)

References 92 publications

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“…In Figure (top), we plot vorticity structures in RST with large‐scale eddies due to the influence of rotation, at the border of which strong small‐scale vortex lanes develop because of instabilities such as Kelvin‐Helmoltz or those due to shear. The plot is for a flow with

R e \approx 5.5 \times 1 0^{4}, F r \approx 0.024, R o \approx 0.1, R_{B} \approx 31

, for a decay run on a grid of 4,096 3 points, integrating the Boussinesq equations (see Rosenberg et al, , and references therein for more details).…”

Section: The Bidirectional or Dual Cascades In Turbulencementioning

confidence: 99%

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Helicity Dynamics, Inverse, and Bidirectional Cascades in Fluid and Magnetohydrodynamic Turbulence: A Brief Review

Pouquet

Rosenberg

Stawarz

et al. 2019

Earth and Space Science

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We briefly review helicity dynamics, inverse and bidirectional cascades in fluid and magnetohydrodynamic (MHD) turbulence, with an emphasis on the latter. The energy of a turbulent system, an invariant in the nondissipative case, is transferred to small scales through nonlinear mode coupling. Fifty years ago, it was realized that, for a two‐dimensional fluid, energy cascades instead to larger scales and so does magnetic excitation in MHD. However, evidence obtained recently indicates that, in fact, for a range of governing parameters, there are systems for which their ideal invariants can be transferred, with constant fluxes, to both the large scales and the small scales, as for MHD or rotating stratified flows, in the latter case including quasi‐geostrophic forcing. Such bidirectional, split, cascades directly affect the rate at which mixing and dissipation occur in these flows in which nonlinear eddies interact with fast waves with anisotropic dispersion laws, due, for example, to imposed rotation, stratification, or uniform magnetic fields. The directions of cascades can be obtained in some cases through the use of phenomenological arguments, one of which we derive here following classical lines in the case of the inverse magnetic helicity cascade in electron MHD. With more highly resolved data sets stemming from large laboratory experiments, high‐performance computing, and in situ satellite observations, machine learning tools are bringing novel perspectives to turbulence research. Such algorithms help devise new explicit subgrid‐scale parameterizations, which in turn may lead to enhanced physical insight, including in the future in the case of these new bidirectional cascades.

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R e \approx 5.5 \times 1 0^{4}, F r \approx 0.024, R o \approx 0.1, R_{B} \approx 31

, for a decay run on a grid of 4,096 3 points, integrating the Boussinesq equations (see Rosenberg et al, , and references therein for more details).…”

Section: The Bidirectional or Dual Cascades In Turbulencementioning

confidence: 99%

“…Rotating stratified flows. (top) Vorticity strength on three planes for the decay run analyzed in Rosenberg et al (), where the color map is also given. The grid has 4,096 3 points, N / f = 5, R e = 55,000, F r = 0.024.…”

Section: The Bidirectional or Dual Cascades In Turbulencementioning

confidence: 99%

Helicity Dynamics, Inverse, and Bidirectional Cascades in Fluid and Magnetohydrodynamic Turbulence: A Brief Review

Pouquet

Rosenberg

Stawarz

et al. 2019

Earth and Space Science

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“…Energy dissipation rates, v,p = |D t E v,p |, were computed with isotropic one-dimensional Fourier data, when 2D spectra should have been used [1]. The difference is particularly stark for the strongly anisotropic density dissipation p , with sharp fronts.…”

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Correction to: Variations of characteristic time scales in rotating stratified turbulence using a large parametric numerical study

et al. 2017

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After publication of the paper, an error in computing the ratio γ of kinetic to potential energy transfer times has been detected, which has led the authors to amend two figures, as explained below.Energy dissipation rates, v,p = |D t E v,p |, were computed with isotropic one-dimensional Fourier data, when 2D spectra should have been used [1]. The difference is particularly stark for the strongly anisotropic density dissipation p , with sharp fronts. , as a function of the Richardson number (top) and N/f (bottom), with binning in Ro, with 56 runs being examined [2]. The range of variation of γ is now smaller, and the peak for Ri ≈ 1 is less noticeable. All other conclusions of the paper remain unchanged. Contribution to the Topical Issue "Multi-scale phenomena in complex flows and flowing matter" edited by

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“…The initial conditions of the runs analyzed in this paper all have velocity modes only, and they are centered in the large scales. We know that balanced initial conditions also give a similar scaling with an identical value of k EQ [34]. In the future, we plan to analyze the stationary case, using both isotropic and balanced forcing; this will also allow for longer time statistics.…”

Section: Discussionmentioning

confidence: 99%

Interplay of waves and eddies in rotating stratified turbulence and the link with kinetic-potential energy partition

Marino¹,

Rosenberg²,

Herbert³

et al. 2015

EPL

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The interplay between waves and eddies in stably stratified rotating flows is investigated by means of world-class direct numerical simulations using up to 3072 3 grid points. Strikingly, we find that the shift from vortex to wave dominated dynamics occurs at a wavenumber kR which does not depend on Reynolds number, suggesting that partition of energy between wave and vortical modes is not sensitive to the development of turbulence at the smaller scales. We also show that kR is comparable to the wavenumber at which exchanges between kinetic and potential modes stabilize at close to equipartition, emphasizing the role of potential energy, as conjectured in the atmosphere and the oceans. Moreover, kR varies as the inverse of the Froude number as explained by the scaling prediction proposed, consistent with recent observations and modeling of the Mesosphere-Lower Thermosphere and of the ocean.

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Evidence for Bolgiano-Obukhov scaling in rotating stratified turbulence using high-resolution direct numerical simulations

Cited by 64 publications

References 92 publications

Helicity Dynamics, Inverse, and Bidirectional Cascades in Fluid and Magnetohydrodynamic Turbulence: A Brief Review

Helicity Dynamics, Inverse, and Bidirectional Cascades in Fluid and Magnetohydrodynamic Turbulence: A Brief Review

Correction to: Variations of characteristic time scales in rotating stratified turbulence using a large parametric numerical study

Interplay of waves and eddies in rotating stratified turbulence and the link with kinetic-potential energy partition

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